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1.0 INTRODUCTION
1.1 Scope of the Method
Analytical method GRM066.01A is suitable for the determination of difenoconazole, CGA205375, CGA142856 and CGA71019 (See Figure 1) in water. The limit ofquantitation (LOQ) ofthe method has been established at a 0.10 µg/L (0.10 ppb).
This method satisfies OECD Guidance Document ENV/JM/MONO(2007)17, US EPA Guidelines OCSPP 850.6100(2012) and EC Guidance Documents SANCO/3029/99 Rev 4(2000) and SANCO/825/00 Rev 8.1(20 l 0).
1.2 Method Summary
Environmental water samples were analyzed directly upon treatment with acetonitrile using liquid chromatography tandem mass spectrometry (LC-MS/MS) technique when the instrument sensitivity allows. Alternatively, the water samples were concentrated for CGA71019 analysis using solid phase extraction (SPE) procedures prior to LC-MS/MS analysis. Thus, upon sample loading and SPE cartridge washing, the samples were eluted with 0.5% NRiOH in methanol/water (90/1 O; v/v) from the SPE cartridges and collected. The collected NH4OH containing methanol/water fractions were evaporated under a gentle stream ofnitrogen in a water bath at approximately 40 °C and re-constituted with acetonitrile/H2O (20:80; v/v) then subjected to LC-MS/MS analysis. The LOQ of the method is 0.10 µg/L (ppb) in water.
2.0 MATERIALS AND APPARATUS
2.1 Apparatus
The recommended equipment and apparatus are listed in Appendix 1. Equipment with equivalent performance specifications may be substituted.
2.2 Reagents
All solvents and reagents must be of high purity, e.g. glass distilled/HPLC grade solvents and analytical grade reagents. Particular care must be taken to avoid contamination of the reagents used. Reagents ofcomparable purity may be substituted as long as acceptable performance is demonstrated. A list of reagents used in this method along with details of preparation ofsolutions is included in Appendix 2.
2.3 Preparation of Analytical Standard Solutions
It is recommended that the following precautions should be taken when weighing the analytical materials .
GRM066.01A Page 11 of 128
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1. Ensure good ventilation.
2. Wear gloves and laboratory coat.
3. Prevent inhalation and contact with mouth.
4. Wash any contaminated area immediately.
2.3.1 Stock Solutions
Individual primary stock solutions at the I00 µg/mL concentration level for difenoconazole, CGA205375, CGA142856 and CGA71019 are prepared by dissolving 10.0 mg ofeach compound into individual 100-mL glass volumetric flasks followed by dilution to the mark with 50:50 acetonitrile:water. The amounts weighed should be corrected for its respective % purity.
Alternatively, the appropriate volume of50:50 acetonitrile: water (v/v; HPLC grade) is added to a known amount ofstandard material may be determined using the equation below. The standard concentration is corrected for its chemical purity.
V =WxP xlOOO C
p = Standard purity in decimal form (P(¾)/100)
V = Volume of 50:50 acetonitrile:water required
w = Weight, in mg, of the solid analytical standard
C = Desired concentration of the final solution, (µg/mL) 1000 = Unit conversion factor
In this case, the standard material is weighed directly into an appropriate storage vessel.
2.3.2 Fortification Solutions
A mixed standard solution at the 1.0 µg/mL concentration is prepared by combining 1.0 mL ofeach primary stock standard into a 100-mL volumetric flask and filling to the mark with 20:80 acetonitrile:water (v/v; HPLC grade). Serial dilutions ofthis mixed standard solution are prepared in 20:80 acetonitrile:water (v/v; HPLC grade) to create mixed fortification standards. It is recommended that the following solutions are prepared: 1.0 µg/mL, 0.10 µg/mL and 0.01 µg/mL for fortification purposes.
2.3.3 Standards for LC-MS/MS
Cal ibration standard solutions should be prepared by serial dilution in acetonitrile/water (20/80; v/v; HPLC grade) from the stock solution or fortification solution. For example, transfer l OmL of the 1.0 µg/mL fortification standard into a 100-mL volumetric flask and diluted with acetonitrile/water (20/80; v/v; HPLC grade) solution to the mark to yield a calibration standard solution at 0.10 µg/mL concentration .
GRM066.0IA Page 12 of 128
• A calibration curve should be generated for each analyte to quantify residues. Standards over an appropriate concentration range should be prepared as described above, using the requisite volume of the mixed standard in acetonitrile/water (20/80; v/v; HPLC grade) solution. A
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minimum offive levels ofcalibration standards should be used for calibration plot establishment. The fo llowing concentration levels ofstandards are prepared for difenoconazole, CGA205375, CGA142856 and CGA 71019 calibration plots: 0.025 pg/µL, 0.05 pg/µL, 0.1 pg/µL, 0.20 pg/µL, 0.50 pg/µL, 1.0 pg/µL, 2.0 pg/µL 5.0 pg/µL and I 0 pg/µL. Single point calibrations are not recommended for this method.
Typical chromatograms from LC-MS/MS analysis of the standard solutions are shown in Figures 7-11
2.3.4 Standard Solution Storage and Expiration
All stock solutions should be stored in a refrigerator when not in use to prevent decomposition and/or concentration of the standard. Standard solutions should be allowed to equilibrate to room temperature prior to use.
An expiration date ofsix months for all compounds is recommended unless additional data are generated to support a longer expiration date.
2.4 Safety Precautions and Hazards
The following information is included as an indication to the analyst of the nature and hazards of the reagents used in this procedure. If in any doubt, consult the appropriate MSDS or a monograph such as 'Hazards in the Chemical Laboratory', edited by S. G. Luxon, The Chemical Society, London (Reference 1).
Solvent and Reagent hazards
Acetonitrile Methanol Formic Acid Ammonium Hydroxide
Harmful Vapour ✓ ✓ ✓ ✓
Highly Flammable ✓ ✓ • • Harmful by Skin Absorption ✓ ✓ ✓ ✓
Irritant to respiratory system and eyes ✓ ✓ ✓ ✓
Causes severe bums • • ✓ ✓
Syngenta Hazard Category (SHC) SHC-C, S SHC-C, S SHC-D,S SHC-D, S
OES Short Term (mglm3) 105 310 NIA 24
OES Long Term (mg/m3) 70 260 NIA 17
• NIA not known
GRM066.01A Page 13 of 128
• Syngenta Hazard Classification for difenoconazole has been assigned as SHC-B.
At present there are insufficient data available to assign a Syngenta Hazard Classification for CGA205375, CGA142856, and CGA71019. These compounds should be treated as a category SHC-D compounds until further information indicates otherwise. The Syngenta Hazard Category scale rates highly toxic chemicals as category SHC-E and non-toxic chemicals as category SHC-A. An additional hazard category ofS indicates the compound is a severe skin and eye irritant.
In all cases avoid breathing vapor. A void contact with eyes and skin.
3.0 ANALYTICAL PROCEDURE
In order to verify method performance and allow recovery corrections to be made (if appropriate), fortified control samples should be included in each sample set. At least one untreated control and two control samples fortified with a known amount ofeach analyte using the mixed fortification standard solution should be analyzed alongside each batch of samples to demonstrate acceptable performance of the method and allow recovery corrections to be made ifdesired. Note that plastic containers should be avoided due to suspected difenoconazole and CGA205375 strong surface interactions with plastic materials.
• A summary ofthe method is included in flow-chart as shown in Appendix 4 .
3.1 Sample Preparation (Difenoconazole, CGA205375 and CGA142856)
a) Ifwater samples are received frozen they should be allowed to defrost completely at room temperature. Defrosted samples should be shaken thoroughly to ensure sample homogeneity prior to subsequent aliquot for further treatment or analysis.
b) Fortification sample preparation: Transfer 10 mL ofwater sample to be analyzed into a 20-mL glass scintillation vial. Fortify the recovery sample with the appropriate amount ofeach analyte using the mixed standard using no more than 0.1 mL. Cap the scintillation vial securely and shake gently to mix thoroughly. Proceed to Section 3.1. C.
c) Water samples (including recovery samples): Transfer 0.8 mL ofwater sample to a 2-mL injection vial containing 0.2 mL acetonitrile. Cap securely and mix sample using a vortex mixer. Samples can be further diluted in acetonitrile/water (20/80; v/v; HPLC grade) solution, if needed. Analyze sample using LC-MS/MS for residue determination.
d) Ifadequate sensitivity is not available for the direct injection ofCGA71019, see Section 3.2 for a SPE/concentration procedure. The method development phase using the AB Sciex API 4000 triple quadrupole mass spectrometer did not allow for direct injection analysis ofCGA71019 .
• GRM066.0IA Page 14 of 128
• During the Independent Laboratory Validation of this method, TK0180143, samples were analyzed using the AB Sciex Triple Quad™ 6500 LC-MS/MS System demonstrating that adequate sensitivity was achieved to allow for direct injection for the CGA71019 analysis, therefore, omitting the SPE/concentration step.
3.2 Solid Phase Extraction Procedure - Bond Elut Certify Cartridges - 300 mg, 3cc- (CGA71019)
a) Fortification samples: Transfer IO mL of water sample to be analyzed into a 20-mL glass scintillation vial. Fortify the recovery sample using no more than 0.1 mL ofthe standard solution. Cap the vial securely and shake gently to mix thoroughly.
b) Condition Certify 300mg 3cc solid phase extraction cartridges as follows:
a. Fill cartridges with methanol (MeOH), twice. b. 2 mL of0.5 % ammonium hydroxide in 90:10 MeOH/H2O, twice. c. 2 mL ofHPLC H2O, twice. d. 2 mL of 5% formic acid in MeOH, twice. e. 2 mL of2% formic acid in H2O, once.
• c) For all samples: A 5 mL aliquot ofeach sample was loaded to their respective SPE cartridges. The sample load was allowed to drip through the cartridge under gravity and the load was discarded.
d) Each cartridge was then washed as follows:
a. 2 mL ofHPLC Grade water, twice. b. 1 mL ofMeOH, twice. All washes were discarded.
e) Residues were eluted with three portions each of2 mL of 0.5% ammonium hydroxide in 90:10 MeOH/ H2O. All eluents were collected in a 15-mL glass centrifuge tube.
f) Eluents were evaporated under a nitrogen stream at 40 °C to approx. 0.5 mL.
g) Samples were reconstituted with 0.2 mL ofacetonitrile and brought to a final volume of 1.0 mL with HPLC water.
h) Samples were sonicated to dissolve any residues and vialed for LC-MS/MS analysis .
• GRM066.0IA Page 15 of 128
• 3.3 Problems and Modifications
a) The SPE procedure has been developed using cartridges from the stated
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manufacturer. Similar cartridges from other manufacturers may be used. In all cases however, it is strongly recommended that the elution profile of the chosen batch ofcartridges is checked prior to commencing analysis to assess any variation in manufacturers' products and between batches.
b) Bottled Optima grade ultra pure water is used to prepare the LC mobile phase, which produces a lower background noise in the MS/MS chromatograms than water taken from a laboratory water purification system.
c) To minimize possible carry-over issues, it is recommended that high level recoveries ~ 10 ppb), samples and standards with similar expected residues include blank injections ofHPLC solvent blanks (acetonitrile/water; 20/80; v/v) following high level injections to observe possible carry-over greater than 10% of the LOQ. Difenoconazole has a strong tendency to adhere to the injection needle in some types ofauto samplers not utilizing flow through needle cleaning. It is important to determine the best wash solutions for the needle washing to reduce the peak response in solvent blanks to <I%.
3.4 Time Required for Analysis
For direct injection, the methodology is normally performed with a batch of20 samples. One skilled analyst can complete the analysis of20 samples in 1 day (8 hour working period).
For water samples requiring concentration (CGA71019) by solid phase extraction (SPE) prior to LC-MS/MS analysis, a batch of 8-10 samples can be analyzed in 1 day (8 hour working period).
3.5 Method Stopping Points
The analytical procedure can be stopped at various points for overnight and weekends unless otherwise specified in the analytical procedure. Acceptable method recoveries will validate any work flow interruptions. Samples should be stored refrigerated in sealed containers where the analysis cannot be completed in a single day.
4.0 FINAL DETERMINATION
An integrated AB Sciex Triple Quad™ 6500 mass spectrometer was used to establish and validate the method. The system is controlled and data is processed by AB Sciex Analyst™ Software. Other instruments may also be used, however optimization may be required to achieve the desired separation and sensitivity. The operating manuals for the instruments should always be consulted to ensure safe and optimum instrument operation.
• GRM066.01A Page 16 of 128
• The following instrumentation and liquid chromatographic conditions are suitable for analysis ofdifenoconazole, CGA205375, CGA142856 and CGA71019.
For difenoconazole and CGA205375, final determination by LC-MS/MS using two transitions is considered to be highly specific; therefore no further confirmatory conditions are included.
For CGA142856 and CGA71019, final determination by LC-MS/MS is accomplished using one transition due to the low molecular weight of the parent compounds. Confirmatory procedures can be found for CGA142856 and CGA 71019 in the following references:
a) For CGA142856 and CGA71019, alternative chromatographic conditions have been documented in Syngenta Report Number T013656-05 (Reference 3).
b) For CGA 71019, alternative chromatographic conditions have been documented in Syngenta Report Number 444-00 (Reference 4).
4.1 Instrument Description/Operating Conditions for Difenoconazole, CGA205375, CGA142856 and CGA71019
M 0 b"I1 e p: hase compos1t100
• HPLC System: Agilent 1290 Infinity Series (UHPLq
Flow Rate: 500 µUmin
Column: Agilent Zorbax SB-Aq 4.6 x 75 mm, 3.5 µm
Column temperature: 40 °C
Injection Volume: 20 µL
Mobile Phase A: 0.3% Formic acid in Water
Mobile Phase B: Acetonitrile:methanol (70:30)
Gradient Step Table: Step Total Time
(min) A(%) B (%)
0 0.0 95 5.0
I 0.5 95 5.0
2 1.5 5.0 95
3 5.0 5.0 95
4 5.1 95 5.0
5 7.0 95 5.0
The retention time may vary depending upon chromatographic conditions and systems.
Retention times for each analyte under these conditions: I) Difenonconazole: 3.53 min 2) CGA205375: 3.36 min 3) CGA142856: 2.11 min 4) CGA71019: 2.08 min
• GRM066.01A Page 17 of 128
• Mass S,pectrometer Con d1h..ons: Mass Spectrometer Detector:
ABSciex Triple Qua<fTM 6500 LC-MS/MS System
Polarity: Positive
CUR: 35.0
IS 3500
CAD: 10.0
TEM: 550
GSI: 70.0
GS2: 70.0
EP: 10.0
MRM O1pera fmg parame ters: MRM Retention
QJ Mass (Da) Q3 Mass(Da) DP CE CXPConditions Time (min)
Quantification Ions
Difenoconazole 406.2 251.0 3.5 90.0 35.0 13.0
CGA205375 350.1 1 69.9 3.3 70.0 55.0 8.0
CGA142856 128.1 70.0 2.3 50.0 25.0 8.0
CGA71019 70.0 43.1 2.1 140.0 28.0 7.0
Confirmation Ions • Difenoconazole 406.2 187.9 3.5 90.0 60.0 10.0
CGA205375 352. 12 69.9 3.3 70.0 55.0 8.0 I j)CGA205375 with all Cl
2 37CGA205375 with one Cl
Optimization of an instrument can be conducted by infusing standard solutions of Difenoconazole, CGA205375, CGA142856 and CGA71019{ 0.1 µg/mL) in mobile phase directly into the mass spectrometer interface at a rate at ofapproximately 7 µL/min (Appendix 3).
Typical LC-MS/MS chromatograms from analysis ofwater samples are shown in Figure Section .
• GRM066.0IA Page 18 of 128
• 5.0 CALCULATION OF RESULTS
5.1 Multi Point Calibration Procedure
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Residues may be calculated in ppb for each sample as follows:
a) Prepare standard solutions over a concentration range appropriate to the expected residues in the samples (for example, 50% LOQ to 20 x LOQ). An appropriate number ofdifferent concentrations within this range should be prepared (at least five levels).
b) Make an injection ofeach sample solution and measure the areas ofthe peaks corresponding to respective ms/ms transition. Calibration standard solutions should be interspersed throughout the analysis, after a maximum offour injections of sample solutions.
c) Generate calibration curve parameters using an appropriate regression package.
d) The following equation can be rearranged and used to calculate residues as follows:
y=mx+c
Where y is the instrument response value, xis the standard concentration, m is the gradient (slope) of the line ofbest fit ("X-variable 1" in MS Excel) and c is the intercept value. An example of this equation generated using the experimental values ofm and c should be included in the raw data, as should the "R-Squared" value for the regression.
Re-arrangement for x gives
y-c x=-
m
e) Calculate residues of interest in a sample, expressed as µg/L, as follows:
Analyte Found (PB) Residue (µ9/L orppb) = -------------
Water Sample Injected (mg or µL)
Where on-column Analyte Found (pg) is calculated from the standard calibration curve and on-column Water Sample (matrix) Injected is calculated as follows:
Water Sample Injected (mg or µL) Injection Volume (µL)= Sample Volume mL X ________ ....:..._....:...__( )
Sample Final Volume (mL)
• GRM066.01A Page 19 of 128
• t) Determine the recovery by first subtracting the residue found in the control sample, if any, from the residue found in the recovery sample. Calculate the recovery as a percentage(%) by the equation:
(Residue in Rec011erySample) - (Residue in Control)( )Recovery % = A F ·t. d x 100%mount orti 1e
g) Ifresidues need to be corrected for average percentage recovery, e.g. for storage stability studies, then the equation below should be used.
Residue (.µg/Lorppb)Corrected Residue (µg/L or ppb) =
Average Precent Recovery
5.2 Single Point Calibration Procedure
Although single point calibration may be used to quantify residues, it is recommended that a calibration curve is generated with each analytical run to demonstrate the linearity of instrument response (Reference 2).
Residues may be calculated in µg/L (ppb) for each sample using a mean standard response from each ofthe injections bracketing the sample as follows.
• a) Make repeated injections ofa standard at an appropriate concentration into the LC
MS/MS operated under conditions as described in Section 4. When a consistent response is obtained, measure the peak areas for each analyte.
b) Make an injection ofeach sample solution and measure the areas of the peaks corresponding to the quantitating analyte.
c) Re-inject the standard solution after a maximum offour injections ofsample solutions.
d) Calculate the residues in the sample, expressed as µg/L (ppb) using a mean standard response from each of the injections bracketing the sample as follows:
PK area (SA) Standard Cone. Residue (µ9/L orppb) = ------ X ------
PK area (STD) Sample Cone.
PK area (SA)= Peak response for sample
PK area (STD) =Average peak response for bracketing standards
Standard Cone. = Concentration ofstandard (µg/mL)
Sample Cone.= Sample concentration (L/mL)
e) Ifresidues need to be corrected for average percentage recovery e.g. for storage stability studies, then the equation below should be used.
• Residue (pgIL or ppb)
Corrected Residue (µg/L orppb) = Average Precent Recovery
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6.0 CONTROL AND RECOVERY SAMPLES
Control samples should be analyzed with each set ofsamples to verify that the sample used to prepare recovery samples is free from contamination. A minimum ofone control should be analyzed with each batch ofsamples.
At least two recovery samples (control samples accurately fortified with known amounts of analyte), including one at the method LOQ and one at the expected residue level, should also be analyzed alongside each set ofsamples. Provided the recovery values are acceptable they may be used to correct any residues found in the sample. The fortification levels should be appropriate to the residue levels expected in the sample.
Recovery efficiency is generally considered acceptable when the mean values are between 70% and 110% and with a relative standard deviation of~ 20%.
When the method is used for monitoring purposes, control and recovery samples are not required where suitable control samples are not available.
7.0 SPECIFICITY
It is recommended that reagent blank samples be included in a sample set ifcontamination is suspected .
7.1 Matrix
No significant matrix effects were observed in the water types tested during method development and non-matrix standards should generally be used for quantification.
7.2 Reagent and Solvent Interference
No interference has been observed from using ofhigh purity solvents and reagents.
7.3 Labware Interference
All reusable glassware should be detergent washed and then rinsed with HPLC grade methanol, acetone or acetonitrile prior to use.
7.4 Potential Interferences
During the validation study (TK0180143), using AB Sciex Triple Quad™ 6500 system, a second peak with significant intensity was observed in standard and fortified-sample chromatograms ofCGA71019 (m/z 69.9-+ 43.1). This second peak has a retention time close to the expected retention time ofCGA 71019; however, it was not observed in previous development/validation work using AB Sciex API 4000 system. At the request of the study monitor, experiments were prepared to determine the source of the second peak (as per ILV
GRM066.01A Page 21 of 128
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protocol Amendment l ). These experiments included the injection ofsingle and mixedanalyte standards ofCGA142856 and CGA71019, and also full product ion scans. These experiments demonstrate the second peak originates from possible in-source fragmentation of the parent ion ofCGA142856 (mass 129) to the parent ion of CGA71019 (mass 69) and a fragment ion (mass 43) common to both CGA142856 and CGA71019. Product ion scan of a CGA142856 standard and extracted-ion chromatograms ofCGA71019 and CGA142856 are presented in Appendix 5 ·
8.0 METHOD VALIDATION
8.1 Recovery Data and Repeatability
Method validations have been carried out on the procedures described in Sections 3.0 and 4.0 ofGRM066.01A. The method validation data are reported in TK0180143 report (Reference 5) and summaries are included in Tables 2-19.
8.2 Limit of Quantitation (LOQ)
The limit ofquantitation of the method is defined as the lowest analyte concentration in a sample at which the methodology has been validated and a mean recovery of70-110% with a relative standard deviation of~ 20% has been obtained. Generally, for accurate quantitation, the response for an analyte peak should be no lower than four times the mean amplitude of the background noise in an untreated sample at the corresponding retention time .
The limit ofquantitation (LOQ) ofthe analytical method has been established at 0.10 µg/L (ppb), which is equivalent to 0.0016 ng on column.
8.3 Limit of Detection (LOD)
The limit ofdetection of the method is defined as the lowest analyte concentration detectable above the mean amplitude of the background noise in an untreated sample at the corresponding retention time. An estimate of the LOD can be taken as three times background noise. Note that the LOD may vary between runs and from instrument to instrument.
The limit ofdetection of the analytical method was estimated to be 0.025 µg/L (ppb), which is equivalent to 0.0005 ng on column with AB Sciex Triple Quad™ 6500 instrument.
8.4 Matrix Effects
No significant matrix effects were observed in the water types tested during method validation and non-matrix standards should generally be used for quantification. A summary of the matrix effects is included in Table 24.
GRM066.0lA Page 22 of 128
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8.5 Detector Linearity
For accurate quantitation of residue concentrations, analyses should be carried out within the linear range of the detector. For multi-point calibration, detector range and linearity will be demonstrated within each sample set.
The linearity of the LC-MS/MS detector response for difenoconazole, CGA205375, CGA142856 and CGA71019 was tested in the range from 0.025 µg/L to 10.0 µg/L concentrations injected (equivalent to 0.50 pg to 200 pg standards on-column when using a 20 µL injection volume) and was found to be linear during the validation using the AB Sciex 6500 triple quadrupole mass spectrometer.
Ifa residue beyond the tested concentration range is expected, dilute the sample appropriately to bring it within the tested linear range prior to quantification is recommended.
Nine different standard concentration levels were injected and the response plotted against the standard concentration (i.e. analyte found) during method development for difenoconazole, CGA205375, CGA142856 and CGA71019 using Analyst™ software version 1.6.2 software. Representative plots ofthe detector responses versus the analyte concentration (pg found) for all calibration points from method testing are presented in Figures 2-6.
8.6 Final Extract Stability
Final water samples in acetonitrile/water (20/80; v/v; HPLC grade) solution retained in vials were found to be stable for at least 19 days upon storage at temperature ofapproximately 5° ± 2 °C during method validation. A summary of the stability data is presented in Table 20-23. It is not recommended to store for more than 7 days for accurate determination of residues. It is recommended to analyze the samples as soon as possible.
9.0 LIMITATIONS
The method has been tested on representative water types. It can reasonably be assumed that the method can be applied to other water matrices not tested in this method provided successful recovery tests at the relevant levels validate the suitability of the method.
10.0 CONCLUSIONS
This procedure has been demonstrated to be a reliable and accurate procedure for the determination of residues ofdifenoconazole, CGA205375, CGA142856 and CGA71019 in environmental water. Only commercially available laboratory equipment and reagents are required. The direct analysis of20 water samples can be completed by one skilled analyst in 1 day (8 working hour period). For water samples concentrated for CGA71019 analysis using solid phase extraction (SPE) procedures prior to LC-MS/MS analysis, a batch of8-10 samples can be analyzed in 1 working day (8 working hour period) .
GRM066.01A Page 23 of 128
• Untreated and fortified samples should be analyzed with each set ofsamples to demonstrate absence ofany interference and adequate recoveries, ifpossible. The LOQ ofthe method is 0.10 µg/L (ppb) for difenoconazole, CGA205375, CGA142856 and CGA71019 in water
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samples.
This method satisfies OECD Guidance Document ENV/JM/MONO(2007)17, US EPA Guidelines OCSPP 850.6100 (2012) and EC Guidance Documents SANCO/3029/99 rev 4 (2000) and SANCO/825/00 rev 8.1 (20 I 0) .
TK.0180148 Method GRM066 OJA.doc sbh: 4/11/14
• GRM066.0IA Page 24 of 128
• 11.0 REFERENCES
1. Luxon S G (1992): Hazards in the Chemical Laboratory 5th Edition. The Royal Society ofChemistry. Thomas Graham House, The Science Park, Cambridge CB4 4WF, UK. ISBN 0-85186-229-2.
2. Cardone M J, Palermo P J and Sybrand LB: Potential error in single point ratio calculations based on linear calibration curves with a significant intercept. Anal Chem., 52 pp 1187-1191, 1980
3. Russell Gottschalk, Environ-Test Laboratories, Edmonton, Alberta T6E OPS Canada, Enviro-Test Method M 314, Syngenta Number TO 13656-05, December 15, 2005
4. Philip Cassidy, Ricerca Biosciences, LLC Concord, 7528 Auburn Road, Concord, Ohio, Ricerca Study Number 0 1673-1, Syngenta Number 444-00, May 4, 2004
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5. Perez, R., M., Patel, D., Perez, S., "Difenoconazole - Independent Laboratory Validation ofResidue Method (GRM066.01A) For the Determination of Difenoconazole, CGA205375, CGA142856 and CGA71019 in Water by LC-MS/MS", ADPEN Laboratories, Inc., 11 1757 Central Parkway, Jacksonville, FL 32224, USA, ADPEN Study No.: ADPEN-2K13-901-TK0180143, Syngenta Study No.: TK0180143, March, 20, 2014 .
• GRM066.0IA Page 25 of 128
• FIGURE 1 Chemical Structures
Compound Code Number : CGA169374 (Difenoconazole)
Alternative Compound Code Number
CASNumber 119446-68-3 IUPACName l-{2-[2-Chloro-4-( 4-chloro-phenoxy)-phenyl]-4-
methyl-[l ,3]dioxolan-2-ylmethyl }-1H-[ l ,2,4]triazole Molecular Formula C19 H11 ChN3 0 3 Molecular Weight
Molecular Mass
• Cl
Compound Code Number : CGA205375 Alternative Compound Code Number
CASNumber 1170I8-19-6 llJPAC Name l-[2-Chloro-4-( 4-chloro-phenoxy)-phenyl]-2-1,2,4-
triazol-l-yl-ethanol Molecular Formula C16 H13 Ch N3 0i Molecular Weight
Molecular Mass
• GRM066.01A Page 52 of 128
• FIGURE 1 Chemical Structures (Continued)
Compound Code Number: CGA142856
Alternative Compound Code Number
CAS Number 28711-29-7
IUPAC Name l ,2,4-Triazol-1-yl-acetic acid
Molecular Formula C4 Hs N3 0 2 Molecular Weight
Molecular Mass
N -;:::::'\ ~ N\
N p o HO
• Compound Code Number : CGA71019
Alternative Compound Code Number
CAS Number 288-88-0
IUPACName 4H- l ,2,4-Triazole Molecular Formula C2 H3 N3 Molecular Weight
Molecular Mass
• GRM066.01A Page 53 of 128
• APPENDIX 1 Apparatus
Recommended Suppliers
•
Equipment Description Supplier
General lab glassware www.thermoscientific.comGeneral lab glassware
General lab plastic-ware General lab plastic-ware www.thermoscientifie.com
Sample processing Waters Extraction www.waters.com station/Vacuum manifold Manifold
Bond Elut-Cl8; www.agilent.com cartridges Solid Phase Extraction
100 mg, 3-mL
Suitable for various www.Biotage.com sizes of reservoirs
Column connectors
www.Biotage.com
Autosampler vials
Column reservoirs Various sizes
Snap cap, 2 mL size www.thermoscientific.com
LC-MS/MS system www.absciex.com/
Includes HPLC and AB Sciex API 4000 and AB Sciex Triple
autosampler units Quad ™ 6500 LC-MS/MS systems
HPLC column www.agi lent.com
75 mm i.d., 3.5 µm particle size
Agilent SB-AQ, 4.6 x
• GRM066.0IA Page 120 of 128
• APPENDIX 2 Reagents
Recommended Suppliers
Reagent
Ultra pure water
Methanol
Ultra pure water
Acetonitrile
Formic Acid
Ammonium Hydroxide
Difenoconazole analytical standard
CGA205375 analytical standard
CGA 142856 analytical
• standard
CGA 71019 analytical standard
Preparation of Reagents
Description
Optima grade
Optima grade
HPLCgrade
HPLCgrade
A.C.S. grade
A.C.S. grade
GLP certified
GLP certified
GLP certified
GLP certified
Supplier
www.thermoscientific.com
www.thermoscientific.com
www.thermoscientific.com
www.thermoscientific.com
www.thermoscientific.com
www.thermoscientific.com
Syngenta Crop Protection, LLC, P.O. Box 18300, Greensboro, NC 27419-8300.
Syngenta Crop Protection, LLC, P.O. Box 18300, Greensboro, NC 27419-8300.
Syngenta Crop Protection, LLC, P.O. Box 18300, Greensboro, NC 27419-8300.
Syngenta Crop Protection, LLC, P.O. Box 18300, Greensboro, NC 27419-8300.
a) "0.3%" formic acid in water; prepared by mixing 3 mL offormic acid with 1,000 mL of Optima LC/MS grade water.
b) "Acetonitrile/Water (20/80; v/v; Optima LC/MS grade): prepared by mixing 200 mL ofOptima LC/MS grade acetonitrile with 800 mL ofOptima LC/MS grade water.
c) "0.5%" ammonium hydroxide in 90/10 MeOH/Water (HPLC grade): prepared by mixing 5.0 mL of ammonium hydroxide with 1,000 mL of90/10 MeOH/Water (HPLC grade)
d) ''2.0%" Formic Acid in H20; prepared by mixing 20 mL offormic acid w ith 980 ml of Optima LC/MS grade water.
e) " 5.0%" Formic Acid in MeOH; prepared by mixing 50 mL of formic acid with 950 mL ofHPLC grade MeOH.
f) Methanol/Water (90/ 10; v/v; HPLC grade): prepared by mixing 900 mL of HPLC grade MeOH with 100 mL ofHPLC grade water.
g) Acetonitrile/Methanol (70/30; v/v; HPLC grade): prepared by mixing 700 mL of Optima LC/MS grade acetonitrile with 300 mL of Optima LC/MS grade MeOH.
• GRM066.01A Page 121 of128
• APPENDIX 3 LC-MS/MS Tuning Procedure
Calibration ofInstrument
The instrument must be mass calibrated on a regular basis using polypropylene glycol (PPG) solutions according to the manufacturer's instructions. Calibrate both mass resolving quadrupoles (Ql and Q3).
Tuning Instrument
Infuse individual standard solutions (0.1 µg/mL) in mobile phase (see section 4) directly into the mass spectrometer interface at a rate at of approximately 7µUm in. Roughly adjust interface parameters (sprayer position and temperature, spray, heater/auxiliary gas flows, as well as voltages of spray, orifice, and focusing ring) for a sufficiently high parent ion signal at m/z in positive ionization mode.
Comoound Parent ion shmal m/z Difenoconazole 406.2
CGA205375 350.1 CGA142856 128.1 CGA71019 69.9
• Using the Analyst software quantitative optimization routine, tune the instrument, ensuring that the correct ions (See Section 4.0) are selected. Ifdesired, manual tuning of the ion optics and collision energy can be carried out to ensure maximum sensitivity.
Finally, connect the LC-pump via the autosampler directly to the MS/MS instrument. Perform repetitive flow injection of the infusion standard using mobile phase at the flow rate to be used. Tune the interface parameters (sprayer position, spray and heater gas flows, spray, orifice, and focusing ring voltages) and the collision gas flow for maximum sensitivity.
In positive mode, the molecular ion generated in the ion source is selected and subjected to further fragmentation by collisional activation. The most sensitive product ions are then selected and used for quantitative analysis.
Compound Parent ion shmal (m/z)
Product Ions
Difenoconazole 406.2 251.0, I 87 .9 CGA205375' 350.1 69.9 CGA205375 ' 352.1 69.9
CGA142856 128.l 69.9 CGA71019 69.9 43.l
j)1cGA205375 with all Cl 37
2.CGA205375 with one Cl
• GRM066.0IA Page 122 of 128
• For difenconazole and CGA205375, final determination by LC-MS/MS using two transitions is considered to be highly specific; therefore no further confirmatory conditions are included.
For CGA205375 and CGA142856, final determination by LC-MS/MS is accomplished using one transition due to the low molecular weight of the parent compounds. Confirmatory procedures can be found for CGA142856 and CGA71019 in the following references:
a) For CGA142856 and CGA71019, alternative chromatographic conditions have been documented in Syngenta Report Number TO13656-05 (Reference 3).
b) For CGA71019, alternative chromatographic conditions have been documented in Syngenta Report Number 444-00 (Reference 4) .
•
• GRM066.0IA Page 123 of 128
• APPENDIX 4 Method Flow Chart
Transfer sample (10.0 mL) to a glass vial
Fortify recovery sample, ifneeded
Mix well by agitation (vortex)
Sample analysis by direct injection for (Difenoconazole, CGA205375. CGA 142856
and CGA71019)
• Transfer 0.8 mL ofsample into HPLC vial
containing 0.2 mL ofACN
t Analysis by LC-MS/MS
• GRM066.01A
Sample analysis by SPE cleanup for CGA710.19, if needed
t Bond Elut Certify (300 mg, 3cc)
t Condition the SPE cartridges
Load the water samples quantitatively
Wash SPE cartridges
Elute the SPE cartridges
with basic 90/10 methanol/water and collect
Evaporate to ~ 0.5 mL
Re-constitute the sample by adding 0.2 mL ACN and bring up to 1.0 mL with water.
Analyze by LC-MS/MS
Page 124 of 128